反应堆安全壳内氧化碘纳米粒子的形成模型

IF 0.9 Q4 ENERGY & FUELS
D. S. Sinitsyn, D. A. Nazarov, N. A. Mosunova, A. A. Sorokin
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引用次数: 0

摘要

介绍了核反应堆安全壳容积内氧化碘纳米粒子在辐射-化学反应过程中形成的模型,以及随后形成纳米粒子的聚类。本文介绍了试验计算的结果。放射性碘氧化物纳米粒子是核电厂人员长期暴露于辐射的潜在危险源。即使外壳保持密封,它们也会通过空气通风系统渗透到发电厂外部。此外,计算表明,放射性碘氧化物纳米粒子的形成与气相中挥发性碘化合物的形成密切相关。而且,后者的形成强度在很大程度上取决于空气湿度。所提出模型的主要特点是考虑了在电离辐射照射空气中的氧气和水蒸气时,气相和气溶胶相过程的动力学现象。计算的主要结果证实,在潮湿的大气中,即使空气吸收的辐射能量剂量率相对较低,也有可能形成由碘氧化物组成的气溶胶纳米粒子。同时,水蒸气的辐射分解对氧化碘纳米粒子的大小和浓度影响微弱。然而,考虑到水蒸气辐射分解诱发的辐射分解产物(尤其是氢自由基)的化学作用,会显著影响与氢形成的挥发性碘化合物:HI 和 HOI。所获得的结果尽管是初步的,但却非常重要,因为这些结果表明,在放射性核素释放到反应堆一回路以外的紧急情况下,不可避免地会在反应堆厂房的大气中形成碘氧化物和碘化氢的悬浮纳米粒子。因此,在开发核电厂裂变产物气溶胶的形成和行为模型时,必须考虑到这一机制。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Model for the Formation of Iodine Oxide Nanoparticles within the Reactor Containment

Model for the Formation of Iodine Oxide Nanoparticles within the Reactor Containment

A description is given of the model of formation of iodine oxide nanoparticles in the volume of the containment of a nuclear reactor during radiation-chemical reactions and clustering with subsequent formation of nanoparticles. The results of test calculations are presented. Nanoparticles of radioactive iodine oxides pose a potential hazard as a source of long-term radiation exposure to NPP personnel. They also penetrate outside the power plant through the air-ventilation system even if the enclosure remains sealed. In addition, calculations have shown that the formation of radioactive iodine oxide nanoparticles is closely related to the formation of volatile iodine compounds in the gas phase. Moreover, the intensity of formation of the latter depends significantly on air humidity. The main feature of the proposed model is the consideration of the kinetics of phenomena for processes in both the gas and aerosol phases when exposed to ionizing radiation on oxygen and water vapor in the air. The main result of the calculations is confirmation of the fundamental possibility of the formation of aerosol nanoparticles consisting of iodine oxides in a humid atmosphere even with a relatively low dose rate of radiation energy absorbed by the air. At the same time, radiolysis of water vapor has a weak effect on the size and concentration of iodine oxide nanoparticles. However, taking into account the chemical interaction of radiolysis products, in particular hydrogen radicals, induced by water vapor radiolysis, significantly affects the formation of volatile iodine compounds with hydrogen: HI and HOI. The obtained results, despite their preliminary nature, are important since they indicate the inevitability of the formation of suspended nanoparticles of iodine oxides and hydrogen iodide in the atmosphere of the reactor premises in the event of emergency situations with the release of radionuclides beyond the first circuit of the reactor. Therefore, this mechanism must be taken into account when developing models of the formation and behavior of fission product aerosols at NPPs.

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来源期刊
CiteScore
1.30
自引率
20.00%
发文量
94
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